Intelligent equipment sequencing

ABSTRACT

Systems and methods for sequencing HVAC equipment of an HVAC system using data recorded in situ to build a model capable of making predictions about equipment efficiency and using that information, in combination with predictions about building load, to produce an operational sequence for the HVAC equipment that promotes an improved or optimized overall energy efficiency for the HVAC system. In one embodiment, the process is automated and utilizes Bayesian computational models or algorithms to generate an initial sequence. The process reduces engineering hours and may advantageously provide a means to predict potential sequencing problems for similar types of HVAC equipment.

PRIORITY CLAIM

This application is a continuation of U.S. application Ser. No.14/582,732 filed Dec. 24, 2014, entitled “INTELLIGENT EQUIPMENTSEQUENCING,” which application is incorporated by reference in itsentirety as if fully set forth herein.

FIELD OF THE INVENTION

The present invention generally relates to systems and methods forcontrolling and scheduling equipment in HVAC systems by predictingcooling loads, heating loads and equipment efficiencies using historicalload and efficiency data recorded in situ by building sensors, abuilding automation system (BAS), an equipment automation system or somecombination thereof.

BACKGROUND

Many buildings employ an HVAC system to maintain a comfortableenvironment. The HVAC system provides heating and cooling for thebuildings. Conventionally, local engineering knowledge is used toproduce a sequencing that arranges equipment (chillers, pumps, etc.) bytheir energy efficiency such as using the least efficient equipment onlyunder the most extreme circumstances. To achieve a better energyefficiency and energy savings for the HVAC system, it is typicallyadvantageous to use the equipment with the higher efficiency beforebringing on other equipment that uses more energy to do the same job.

HVAC systems are designed with multiple pieces of equipment, some to dothe same job as other identical pieces of equipment, like chillers inwhich there may be two or more water chillers as part of the building orcampus HVAC system. During low cooling season only one of the chillerswould be operating; whereas during high cooling season maybe all ofthese chillers would be operating. In addition, one or more chillers maybe purposefully kept off line for a variety of reasons such as, but notlimited, repairs, maintenance, etc.

Even though these chillers may be similar or identical (e.g., samemanufacture, same model, etc.), the chillers may often have differentefficiency's for performing the same heating or cooling task. By way ofexample, a chiller efficiency is typically measured as kW/ton (or otherHVAC equipment efficiency measurements like Co-efficient of Performance(COP), Energy Efficiency Ratio (EER), Seasonal Energy Efficiency Ration(SEER)), which is the amount of energy (measured in kw) used by thechiller to produce cooling (measured in tons). A lower kW/ton ratingindicates higher efficiency (tons=one ton of cooling is the amount ofheat absorbed by one ton of ice melting in one day, which is equivalentto 12,000 Btus per hour, or 3.516 kilowatts (kW) (thermal energy)).

A number of different methods have been developed to measure equipmentefficiency and stage equipment by their efficiency ratings. Thesemethods include observation and manual modeling of equipment efficiencyfor certain building conditions (usually including wet bulb airtemperature, building load, etc.) along with use of a manufacturer'sspecification for equipment efficiencies. These parameters are combinedwith engineering knowledge to provide a static sequencing order that maybe used over a period of time to keep energy efficiency high.

While equipment like a chiller is operating, the efficiency of eachoperating chiller may be measured and compared by an engineer, abuilding automation system (BAS) or an energy management system (EMS)with the correct instrumentation. By way of example, some engineers mayspecify the most efficient sequence to run the equipment and thatsequence may be controlled manually by operators or it may be hard codedwithin the BAS to run in that particular sequence in an automatedmanner.

Many of the conventional sequencing methods involve many hours of laboron the part of a knowledgeable engineer and the sequence modelingtypically occurs only at the outset when the equipment is initiallycommissioned. The “stage and forget” process may be problematic sinceequipment energy efficiencies can drift over time as parts or componentswear, critical operating fluids leak or are used up, and/or conditionschange in the system as a whole. Such operational changes directlyaffect the energy usage of individual pieces of equipment.

The reasons that equipment like chillers, pumps, fans, cooling towers orboilers may have different efficiencies may be due to (1) manufacturingdifferences (large or small); (2) poor equipment maintenance; (3)equipment wear or broken parts; (4) contamination or loss of refrigerantwithin a chiller; and/or (5) fouling or buildup of material on workingsurfaces.

FIG. 1 shows a chart 10 in which energy efficiency 12 is recorded overtime 14 for two separate, but otherwise identical chillers 16, 18,respectively. The upper curve 20 shows how the efficiency of firstchiller 16 varies over time while the lower curve 22 shows how theefficiency of second chiller 18 varies over time.

Additionally, while the manual sequencing process may capture trends inequipment efficiency it is often unable to observe small fluctuations inefficiency. Since manufacturer specifications are often used in themanual sequencing process it can also be difficult to perceivedifferences in equipment energy efficiencies for the same model. Thismay result in operating less efficient equipment, using excess energythat may be “left on the table.”

The most predominant and common method to operate and stage equipmentinvolves operating the equipment in an equal runtime rotation scheme.This method rotates the operating sequence of a group of equipment basedon the accumulated running hours (or days, or minutes) of each piece ofequipment. When one piece of equipment has accumulated a certain numberof operational hours than another piece of equipment the operatingsequence is rotated. The equipment having the lowest logged hours isrotated in the operating sequence to turn on first, while the equipmenthaving the highest logged hours will be turned on last in the sequence.

Another method to operate and stage equipment involves using a minimumruntime sequence in which the equipment is staged to ensure that eachpiece of equipment runs for a certain amount of hours every rotationperiod, which is commonly done to make sure that the equipment does notsit inoperable for a long period. When equipment is left inoperable forlong periods of time, the equipment may decay or lose critical operatingfluids to leakage or evaporation.

FIG. 2 shows another chart 24 in which measured energy efficiencies 26are plotted over time 28. Each curve 30, 32, 34 represents the energyefficiencies 26 of three similar chillers respectively, over time. Anupward facing arrow 36 indicates that chiller 30 had the best operatingefficiency for a period of time, but then began operating at a pooreroperating efficiency over a later period of time as indicated by arrow38.

Over time, the energy efficiencies of the equipment may drift as shownin FIG. 2, and such drifts may be result in a reduced or poorer energyefficiency for that particular equipment. On the flip side, a piece ofequipment with a poor energy efficiency may be improved throughmaintenance, repair, or cleaning, for example.

BRIEF SUMMARY OF THE INVENTION

The present invention is generally directed toward systems and methodsfor sequencing HVAC equipment of an HVAC system using data recorded insitu to build a model capable of making predictions about equipmentefficiency and using that information, in combination with predictionsabout building load, to produce an operational sequence for the HVACequipment that promotes an improved or optimized overall energyefficiency for the HVAC system.

In addition, this data, prediction and modeling can be used to determinewhich pieces of HVAC equipment work more efficiently with other piecesof HVAC equipment, taking into account the covariance between thedifferent pieces of HVAC equipment, producing further sequencing thatwill operate the HVAC equipment together in efficient covariancecombinations, that promotes an improved or optimized overall energyefficiency for the HVAC system.

In addition, this data, prediction and modeling can be used to optimizewhen best to stage additional HVAC equipment on or off, based on thefuture load prediction of the HVAC equipment, which promotes an improvedor an optimized overall energy efficiency for the HVAC system.

In addition, this data, prediction and modeling can be used to determineat which loads the HVAC equipment operates at its best efficiency,allowing for the load balancing of the different similar pieces ofoperating HVAC equipment, to keep them operating in their ‘Sweet Spot’,for example if one chiller operates most efficiently at a load of 500tons, it can be load balanced via water flow, valves or control setpoints, to remain operating at that “sweet spot” of 500 tons in parallelwith another operating chiller which operates efficiently at 700 tons,also load balanced to operate producing 700 tons via water flow, valvesor control set points, to remain operating at that “sweet spot”, whichpromotes an improved or optimized overall energy efficiency for the HVACsystem.

In one embodiment, the process is automated and utilizes Bayesiancomputational models or algorithms to generate an initial sequence. Theprocess reduces engineering hours and may advantageously provide a meansto predict potential sequencing problems for similar types of HVACequipment.

In one aspect of the present invention, a method for sequencing HVACequipment in an HVAC system includes the steps of (1) acquiring aplurality of inputs including historical data points and predicted datapoints; (2) determining energy efficiencies for the HVAC equipment; (3)acquiring weather prediction data; (4) using the inputs, energyefficiencies and weather prediction data, computing an expected futureload for the HVAC equipment; (5) using the inputs, energy efficiencies,weather prediction data and expected future load, employing ananalytical computational model to determine predicted energyefficiencies for the HVAC equipment; (6) determining an initial order ofthe HVAC equipment configured to provide an optimized energy efficiencyfor the HVAC system; (7) filtering the initial order based on anoperating status for one or more of the HVAC equipment; (8) determininga final sequence of the HVAC equipment; and (9) providing the finalsequence to a building automation system for controlling the HVAC systemin accordance with the final sequence.

In another aspect of the present invention, a method for sequencing HVACequipment in an HVAC system includes the steps of (1) acquiring aplurality of inputs including historical data points and predicted datapoints; (2) determining energy efficiencies for the HVAC equipment; (3)acquiring weather prediction data; (4) using the inputs, energyefficiencies and weather prediction data, computing an expected futureload for the HVAC equipment; (5) using the inputs, energy efficiencies,weather prediction data and expected future load, employing a linearregression model to determine predicted energy efficiencies for the HVACequipment; (6) determining an initial order of the HVAC equipmentconfigured to provide an optimized energy efficiency for the HVACsystem; (7) filtering the initial order based on an operating status forone or more of the HVAC equipment; (8) determining a final sequence ofthe HVAC equipment; and (9) providing the final sequence to a buildingautomation system for controlling the HVAC system in accordance with thefinal sequence.

In yet another aspect of the present invention, a method for sequencingHVAC equipment in an HVAC system includes the steps of (1) acquiring aplurality of inputs including historical data points and predicted datapoints; (2) determining energy efficiencies for the HVAC equipment; (3)acquiring weather prediction data; (4) using the inputs, energyefficiencies and weather prediction data, computing an expected futureload for the HVAC equipment; (5) using the inputs, energy efficiencies,weather prediction data and expected future load, employing a k-nearestneighbors model to determine predicted energy efficiencies for the HVACequipment; (6) determining an initial order of the HVAC equipmentconfigured to provide an optimized energy efficiency for the HVACsystem; (7) filtering the initial order based on an operating status forone or more of the HVAC equipment; (8) determining a final sequence ofthe HVAC equipment; and (9) providing the final sequence to a buildingautomation system for controlling the HVAC system in accordance with thefinal sequence.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred and alternative embodiments of the present invention aredescribed in detail below with reference to the following drawings:

FIG. 1 is a chart showing two similar pieces of HVAC equipment operatingat different energy efficiencies over time;

FIG. 2 is a chart showing three similar pieces of HVAC equipmentoperating at different efficiencies over time;

FIG. 3 is a schematic system diagram of an equipment sequencing programin on-site communication with a building automation system (BAS) thatcontrols an HVAC system according to an embodiment of the presentinvention; and

FIG. 4 is a schematic system diagram of an equipment sequencing programthat remotely obtains weather data from a weather service provider andwhere the equipment sequencing program is in remote communication withan external optimization application that provides a communicationsinterface for a building automation system (BAS) that controls an HVACsystem according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In the following description, certain specific details are set forth inorder to provide a thorough understanding of various embodiments of theinvention. However, one skilled in the art will understand that theinvention may be practiced without these details. In other instances,well-known structures associated with HVAC systems; automation systems(e.g., building automation systems referred to as BASs); air handlerunits (AHUs) such as, but not limited to terminal units (also called fancoil units), packaged units or rooftop units, and various equipment usedin HVAC systems such as, but not limited to, controllable valves,heating and cooling coils, various types of sensors; controllers andprocessors; communication networks; various computing and/or processingsystems; chillers, fans, various HVAC system equipment operationalparameters and set points, data points or data points; and methods ofoperating any of the above with respect to one or more buildings havenot necessarily been shown or described in detail to avoid unnecessarilyobscuring descriptions of the embodiments of the invention.

One systemic and on-going problem in the HVAV industry is the inabilityto continually model ongoing dynamic efficiency changes of the HVACequipment, and then react to such changes in a meaningful manner such asre-ordering the equipment sequencing to improve overall efficiency andreduce operating costs of the HVAC system.

Even if the labor intensive and time intensive manual sequencing processcould be done quickly, putting the data to use would be expensivewithout an automatic method of generating sequencing orders whileconsidering local operating conditions. Any method that models energyefficiency on a per equipment basis should preferably include anautomation method that produces a sequencing order.

An embodiment of the present invention includes a method forautomatically and dynamically predicting energy efficiency on a perequipment basis and using that information along with local conditionsto choose a sequencing order that increases energy efficiency. Further,the chosen sequencing order may allow for the observation of variousHVAC equipment efficiencies over time, which in turn may provide atechnician or engineer with a better insight about the HVAC system. Theautomation of such a method would advantageously rebalance equipmentloads without requiring direct management, oversight or observation by aknowledgeable technician or engineer. Further, such a method may producereports that highlight any glaring changes in energy efficiency in atimely manner.

FIG. 3 shows a system diagram 100 for providing intelligent equipmentsequencing to a various sets or groups of similar HVAC equipment suchas, but not limited to, chillers, boilers, fans, pumps and coolingtowers. The term “similar” as used herein means the equipment is of asimilar design and size relative to the other equipment. In theillustrated embodiment, the intelligent equipment sequencing occurson-site, for example on a building site or a campus site (e.g., a sitehaving more than one building or HVAC system). The system diagram 100shows the overall process for sequencing similar HVAC equipment by theirrespective energy efficiencies which includes the inputs for the majormodules to complete said sequencing.

The outline or border 102 represents a building or a campus, which inturn includes at least one HVAC system 104 having two or more pieces ofsimilar HVAC equipment 106. In the illustrated embodiment and by way ofexample, the HVAC equipment 106 may take the form of three chillersoperating in parallel, but not necessarily all operating at the sametime.

In the illustrated embodiment, the HVAC system 104 exchanges datato/from the pieces of equipment 106 with a building automation system(BAS) 108. The BAS 108 controls and runs the equipment 106 to meet aload or demand of the building or campus 102. Further, the BAS 108operates as a communications interface between an equipment sequencingprogram 110 and the HVAC system 104.

In operation, data is gathered, in real-time from the equipment 106 andthe HVAC system 104. The data is stored in an equipment and sensordatabase 112 of the BAS 108 and communicated to the equipment sequencingprogram 110 as operating data 114, which uses a Bayesian method tosequence the equipment 106 as will be explained in further detail below.

In the illustrated embodiment, the equipment sequencing program 110utilizes a plurality of inputs 116 such as, but not limited to,historical data points 118, per equipment efficiency 120, predicted datapoints 122 and weather prediction data 124. The historical data points118 have been recorded, observed, measured or otherwise documented at aprior time.

One type of historical data point 118 may include a historical time atwhich the data point was recorded. This historical time may be in theform of a universal time code (UTC), a time stamp, or a record of thetime in minutes and hours (either 12-hour or 24-hour format). Thehistorical time provides various snapshots and periodic thermal dynamicsof the HVAC equipment 106. Another type of historical data point 118 maybe a historical date for when the data point was recorded. Thehistorical date preferably may further indicate whether the data pointwas recorded on a weekend or a weekday, and whether the weekday was aholiday. The historical date information captures load dependencyinformation pertaining to the work schedule of the HVAC system 104 andthe similar HVAC equipment 106 to be sequenced. Other historical datapoints 118 may include a wet bulb outside air temperature, a dry bulbair temperature, and load information of the building or campus. Theload information is used by the equipment sequencing program 110 to bindthe aforementioned historical data points to a specific load value forthe equipment sequencing program.

The per equipment efficiency input 120 is a record of the efficiency ofeach piece of HVAC equipment, which in turn provides specific efficiencyvalues so that future efficiencies may be predicted. In one embodiment,the per equipment efficiency input 120 is recorded in kilowatt per tonsof ice equivalent (it could also be recorded in any other energyefficiency measurement like COP, EER, SEER or IEER).

The inputs 116 further include predicted data points 122. One of thepredicted data points 122 includes predicted time information with timestamps or boundaries for a predetermined future time period underconsideration. Another one of the predicted data points 122 includespredicted date information and whether such date or dates include aweekend day, a weekday or a holiday.

Lastly, the inputs 116 include weather prediction information thatincludes a predicted outside air wet bulb temperature, a predictedoutside air humidity and a predicted outside air dry bulb temperature,both for the future time period under consideration.

The inputs 116 are communicated or otherwise transmitted to a loadpredictor module 126, which computes a future load or loads for the HVACequipment 106 using said inputs 116. In practice, the future load istypically computed for the next day, or for the next 24 hours, but it isappreciated that the future load may be predicted for any reasonable,foreseeable period of time. The load predictor module 126 may assist inpredicting equipment efficiency and may also be used to predict a totalenergy used by the entire HVAC system.

The inputs 116 are also communicated to or transmitted to an equipmentefficiency predictor 128, which generates an efficiency model for all ofthe HVAC equipment 106 to be sequenced. In one embodiment, the equipmentefficiency predictor 128 may take the form of a self-learning modulethat continually updates the efficiency model.

The equipment efficiency predictor 128 may be configured to predict anenergy efficiency of the equipment 106 using data from the inputs 116and load predictor 126. In one embodiment, the equipment efficiencypredictor 128 takes the form of a linear regression model that acceptsat least the historical data points 118 and the prediction data points122 to build a model of the HVAC equipment's 106 energy efficiency. Theequipment efficiency predictor 128 predicts the energy efficiency foreach piece of HVAC equipment 106 at each predicted data point 122. Thelinear regression model scalarizes the data points 118, 122 bytransforming the data points from its native or baseline encoded formatto a scalar value that can be manipulated as a number. Next, a linearregression analysis is performed on the inputs 116 with the timeinformation, the date information, the temperature data, and the load asindependent variables and the equipment's energy efficiency as thedependent variables. The linear regression model accepts the predicteddata 122 and uses the linear regression to make predictions aboutequipment energy efficiency. Each piece of HVAC equipment 106 may haveits own model. The predicted data points 122 along with the predictedefficiency of the HVAC equipment at each predicted data point is thenoutput to an order equipment module 130.

In another embodiment, the equipment efficiency predictor 128 takes theform of a K-nearest neighbors (KNN) model efficiency predictor. This KNNpredictor accepts the historical data points 118 and the predicted datapoints 122 to build a model of the equipment's energy efficiency. Themodel predicts the energy efficiency for each piece of HVAC equipment106 at each predicted data point 122. The KNN model scalarizes the datapoints 118, 122 similar to the linear regression model. Next, the KNNmodel removes data points that contain invalid data values from both thehistorical 118 and predicted data points 122. Each dimension of eachhistorical data point 118 is treated as a random distribution of points.The standard deviation and average of this random distribution iscomputed. All dimensions of each historical data point 118 arenormalized by subtracting the average obtained for that dimension andthen dividing by the standard deviation for that dimension. This processis repeated on the predicted data points 122, except that the sameaverage and standard deviation derived from the normalizing thehistorical data points 118 are used to normalize the predicted datapoints 122. The value of each dimension is re-weighted by multiplyingeach value for that dimension in both the historical and predicted datapoints by a constant re-weighting constant.

The KNN model then accepts the historical data points 118 and placesthem into a KNN space that returns the K neighbors of each inputprediction data point that most closely resemble that point. The modelreturns the average efficiency of the k neighbors for the HVAC equipmentalong with the original predicted data points 122. For each predictiondata point and each piece of HVAC equipment 106, the respective energyefficiency is predicted using the prepared KNN model. Next, theweighting process used is reversed or de-weighted such that eachdimension should have the same weight after thereinafter. Lastly, thenormalization process is also reversed. Each dimension (along with thepredictions of equipment energy efficiency) may be re-scalarized withcorrect values. The predicted data points 122 along with the predictedefficiency of the HVAC equipment 106 at each predicted data point isthen output to the order equipment module 130.

Both the load predictor 126 and equipment efficiency predictor 128forward their data to the order equipment module 130, which uses thisinformation along with the predicted data points 122 to determine anorder of the HVAC equipment 106 by their respective energy efficiency,best operating combinations, best covariance operation and efficientload balancing.

The order equipment module then forwards the order of the HVAC equipment106 to a filter equipment module 132, which determines what equipment isactually available to be sequenced, as some may not be able to run dueto unavailability, minimum runtime, etc. After the HVAC equipment 106 isordered and filtered, that information is transmitted to an outputsequencing module 134.

In the output sequencing module, the data is formatted for consumptionby a receiving device or system and is then transmitted to an equipmentstaging sequence module 136 of the BAS 108. The BAS 108 will take thesequence and use it in conjunction with a BAS equipment control program138 to operate the HVAC equipment 106 in the most efficient waypossible.

Summarizing, one or more embodiments of the present invention providemethods for sequencing HVAC equipment by their respective energyefficiencies. The method accepts two time series as inputs and returnsan equipment ordering. The first time series includes historical datarecorded at the building or campus. The second time series is a set ofpredicted data points. These prediction data points are time seriespredictions for each of the dimensions contained in the historical datapoints over some future time period under consideration by the loadpredictor.

The historical data and prediction data is then fed into a loadpredictor, which in turn uses the historical data to build a model thatcan predict the future load of HVAC equipment given a time series thatcontains a prediction of the environmental conditions for the HVACsystem in the future. This model is used, along with the predicted datapoints, to predict the building load for each data point in thepredicted data points.

The predicted data points, along with the load predicted for each datapoint, are next sent to the equipment efficiency predictor. Thispredictor additionally uses the historical data points. In oneembodiment this efficiency predictor uses a linear regression model.Since the historical data points contain dimensions with diverse datatypes the historical and prediction data points are first scalarized.This process changes each dimension in to a number for use in the linearregression. Next, the scalarized historical data points are modeledusing a linear regression model that returns the equipment's efficiencyas a linear function of the time, the date, the outside air temperature,the outside air wet bulb temperature, and the load. Next, for each datapoint in the predicted data points, the energy efficiency for each pieceof HVAC equipment is predicted using the predicted data points as inputto the model. Further modeling can be done based on best combinationsand covariance operation, and efficient load balancing of the HVACequipment. Finally, the extended prediction data points are output, eachcontaining the information in along with the predicted load andpredicted energy efficiency for the equipment.

In another embodiment the efficiency predictor uses a KNN model topredict energy efficiency for the HVAC equipment rather than a linearmodel. In this process, first the historical data and the predictiondata are scalarized so that each dimension of the data points representa number. Next, the both historical data and prediction data sets arecleaned, with invalid data points removed from both sets. The next stepnormalizes the historical and prediction data points. This is done byfirst finding the average and standard deviation of each dimension inthe historical data set. Next, each dimension in both the historicaldata set and prediction data set is normalized by subtracting theirrespective average from the historical data set and then dividing eachof them by the standard deviation. After normalization each dimension ofthe historical and prediction data sets is re-weighted. This is done bymultiplying each value in each of the dimensions by a constant. Next,the historical data is put into a KNN space which builds a model capableof accepting prediction data points, finding historical data points thatare close to those prediction data points in terms of the independentvariables (time, data, outside air temperature, outside wet bulb airtemperature and load) and returning a value for each of the dependentvariables (efficiency for each piece of equipment). Finally the extendedprediction data points are output after de-weighting by dividing eachdimension by its re-weighting constant and de-normalization, reversingthe normalization process.

The extended prediction data points are then fed into the orderequipment module. In one embodiment, the equipment's predicted energyefficiency is calculated by averaging the predicted energy efficiencydetermined for the equipment over all time steps. The equipment is thenplaced in a list in order of its energy efficiency, with highestefficiency first and lowest efficiency last. In another embodiment, thetotal energy used by the system is predicted for each possible orderingof the HVAC equipment, using the extended prediction data to calculatethe amount of energy the HVAC system would use if it were run with thatordering of the HVAC equipment. In another embodiment, the combinedefficiency and covariance of the HVAC equipment operating together ismodeled and used to extend the prediction data to calculate the leastamount of energy the HVAC system would use if it were run with thatordering and sequence of the HVAC equipment. Finally, the ordering thatuses the lowest amount of energy is returned as the equipment order.

Next, the equipment orderings are filtered. This process uses knowledgeof the current physical state of the HVAC system to remove the pieces ofHVAC equipment that are not available for use. Finally, after equipmentfiltering, a valid equipment sequencing is provided to the BAS forcontrolling the HVAC system.

FIG. 4 shows a system 200 in which data or information is exchangedremotely and/or wirelessly 240. For purpose of brevity and clarity, allcomponents of the system 200 are the same as those illustrated in FIG. 3except the components having 200 level numbers. In other words, anycomponents of system 200 taken from FIG. 3 retain the same number. Inthe system 200, the equipment sequencing program 110 communicatesremotely with an external optimization application module 242, whichfunctions as a communications interface between the equipment sequencingprogram 110 and the BAS 108. The external optimization applicationmodule 242 may include operating data 244 and operating parameters 246related to the HVAC equipment 106. In the illustrated embodiment, theweather prediction 124 may be acquired from a third party weatherservice provider 248 via an application programming interface (API) overthe Internet.

While the preferred embodiment of the invention has been illustrated anddescribed, as noted above, many changes can be made without departingfrom the spirit and scope of the invention. In addition, otheradvantages will also be apparent to those of skill in the art withrespect to any of the above-described embodiments whether viewedindividually or in some combination thereof. Accordingly, the scope ofthe invention is not limited by the disclosure of the preferredembodiment. Instead, the invention should be determined entirely byreference to the claims that follow.

The embodiments of the invention in which an exclusive property orprivilege is claimed are defined as follows:
 1. An equipment-sequencingprocessing device configured to execute a method for sequencing HVACequipment in an HVAC system, the method comprising: acquiring aplurality of inputs including historical weather data and datarepresenting at least one future time period of interest; determiningenergy efficiencies for the HVAC equipment; acquiring weather predictiondata associated with the at least one future time period of interest;using the inputs, energy efficiencies and weather prediction data,computing an expected future load for the HVAC equipment; using theinputs, energy efficiencies, weather prediction data and expected futureload, employing an analytical computational model to determine predictedenergy efficiencies for the HVAC equipment; determining an initialsequence of operation of the HVAC equipment configured to provide anoptimized energy efficiency for the HVAC system; determining theavailability of the HVAC equipment included in the initial order basedon an operating status for one or more of the HVAC equipment;determining, based on the determination of availability of the HVACequipment, a final sequence of the HVAC equipment; and providing thefinal sequence to a building automation system for controlling the HVACsystem in accordance with the final sequence.
 2. The device of claim 1,wherein determining the energy efficiencies includes determiningreal-time energy efficiencies.
 3. The device of claim 1, whereindetermining the energy efficiencies includes determining historicalenergy efficiencies.
 4. The device of claim 1, wherein acquiring theweather prediction data includes obtaining the weather prediction datafrom a third party source.
 5. The device of claim 1, wherein theanalytical computational model is a Bayesian based model using a linearregression analysis.
 6. The device of claim 1, wherein the analyticalcomputational model is a Bayesian based model using a k-nearestneighbors analysis.
 7. An equipment-sequencing processing deviceconfigured to execute a method for sequencing HVAC equipment in an HVACsystem, the method comprising: acquiring a plurality of inputs includinghistorical weather data points and data representing at least one futuretime period of interest; determining energy efficiencies for the HVACequipment; acquiring weather prediction data associated with the atleast one future time period of interest; using the inputs, energyefficiencies and weather prediction data, computing an expected futureload for the HVAC equipment; using the inputs, energy efficiencies,weather prediction data and expected future load, employing a linearregression model to determine predicted energy efficiencies for the HVACequipment; determining an initial sequence of operation of the HVACequipment configured to provide an optimized energy efficiency for theHVAC system; determining the availability of the HVAC equipment includedin the initial order based on an operating status for one or more of theHVAC equipment; determining, based on the determination of availabilityof the HVAC equipment, a final sequence of the HVAC equipment; andproviding the final sequence to a building automation system forcontrolling the HVAC system in accordance with the final sequence. 8.The device of claim 7, wherein determining the energy efficienciesincludes determining real-time energy efficiencies.
 9. The device ofclaim 7, wherein determining the energy efficiencies includesdetermining historical energy efficiencies.
 10. The device of claim 7,wherein acquiring the weather prediction data includes obtaining theweather prediction data from a third party source.
 11. Anequipment-sequencing processing device configured to execute a methodfor sequencing HVAC equipment in an HVAC system, the method comprising:acquiring a plurality of inputs including historical weather data anddata representing at least one future time period of interest;determining energy efficiencies for the HVAC equipment; acquiringweather prediction data associated with the at least one future timeperiod of interest; using the inputs, energy efficiencies and weatherprediction data, computing an expected future load for the HVACequipment; using the inputs, energy efficiencies, weather predictiondata and expected future load, employing a k-nearest neighbors model todetermine predicted energy efficiencies for the HVAC equipment;determining an initial sequence of operation of the HVAC equipmentconfigured to provide an optimized energy efficiency for the HVACsystem; determining the availability of the HVAC equipment included inthe initial order based on an operating status for one or more of theHVAC equipment; determining, based on the determination of availabilityof the HVAC equipment, a final sequence of the HVAC equipment; andproviding the final sequence to a building automation system forcontrolling the HVAC system in accordance with the final sequence. 12.The device of claim 11, wherein determining the energy efficienciesincludes determining real-time energy efficiencies.
 13. The device ofclaim 11, wherein determining the energy efficiencies includesdetermining historical energy efficiencies.
 14. The device of claim 11,wherein acquiring the weather prediction data includes obtaining theweather prediction data from a third party source.